Mems driving device, electronic apparatus, and mems driving method

ABSTRACT

A spectroscopic measurement apparatus includes a fixed substrate, a movable substrate, and a wavelength variable interference filter which includes an electrostatic actuator for changing the gap dimension between the substrates, a vibration disturbance detection unit which detects vibration added to the wavelength variable interference filter, and a bias driving unit which applies a feed-forward voltage based on a detected value of the vibration disturbance detection unit to the electrostatic actuator.

BACKGROUND

1. Technical Field

The present invention relates to an MEMS driving device, an electronicapparatus, and an MEMS driving method.

2. Related Art

In the related art, an apparatus is known which precisely controls thegap dimension between a pair of substrates which face each other (forexample, refer to JP-A-1-94312).

The apparatus disclosed in JP-A-1-94312 is an apparatus which controlsthe gap dimension between a pair of reflection films which areFabry-Perot etalons (wavelength variable interference filter). In theapparatus, the wavelength variable interference filter includes anelectrostatic actuator which controls the gap dimension betweensubstrates, and capacity electrodes which detect the gap dimensionbetween the substrates. In addition, the wavelength variableinterference filter includes a control circuit which controls theelectrostatic actuator, and an electrostatic capacity detection circuitwhich detects the electrostatic capacity between the capacityelectrodes. Further, the control circuit performs feedback control on avoltage, which is applied to the electrostatic actuator, based on theelectrostatic capacity (the gap dimension between the substrates) whichis detected by the electrostatic capacity detection circuit.

However, in the apparatus disclosed in JP-A-1-94312, when high frequencyvibration (hereinafter, referred to as a disturbance signal) is addedfrom outside, it is difficult to sufficiently cope with the vibration byonly performing the feedback control, and thus there is a problem inthat the control performance of the gap dimension between the substratesis deteriorated. For example, in the apparatus disclosed inJP-A-1-94312, the feedback control in which the disturbance vibration istaken into consideration, is not performed, with the result that thereis a problem in that the substrates diverge and vibrate due to thedisturbance vibration when the feedback control is performed, and thus along amount of time is necessary until the gap dimension between thesubstrates reaches a desired value.

SUMMARY

An advantage of some aspects of the invention is to provide an MEMSdriving device, an electronic apparatus, and an MEMS driving methodwhich are capable of performing driving control with high precision whendisturbance vibration is added thereto.

According to an aspect of the invention, there is provided an MEMSdriving device including: an MEMS element that includes a pair ofsubstrates and an electrostatic actuator which changes a gap dimensionbetween the pair of substrates; a vibration detection unit that detectsvibration which is added to the MEMS element; and an actuator controlunit that applies a feed-forward voltage based on a detected value ofthe vibration detection unit to the electrostatic actuator.

According to the aspect, the vibration detection unit detectsdisturbance vibration which is added to the MEMS element, and appliesthe feed-forward voltage to the electrostatic actuator based on thedetected value such that the vibration is suppressed. Therefore, it ispossible to suppress fluctuation in the gap dimension between the pairof substrates due to the vibration of the MEMS element, and thus it ispossible to control the gap dimension between the pair of substrates inthe MEMS element with high precision when the disturbance vibration isadded thereto.

In the MEMS driving device according to the aspect, the electrostaticactuator may include a bias actuator and a control actuator which isprovided independently from the bias actuator, and the actuator controlunit may apply the feed-forward voltage to the bias actuator and appliesa feed-back voltage based on the gap dimension between the pair ofsubstrates to the control actuator.

According to the aspect, the electrostatic actuator includes the biasactuator and the control actuator, and applies the feed-forward voltageto the bias actuator. Here, the bias actuator is an actuator for coarseadjustment and is used to set the gap dimension between a pair ofsubstrates to a desired value, and the control actuator is an actuatorwhich controls the gap dimension with high precision by applying thefeed-back voltage based on the gap dimension. In the electrostaticactuator, the feed-forward voltage is applied to the bias actuator inorder to suppress vibration components due to the disturbance vibrationor the like which is detected by the vibration detection unit, and thusit is possible to suppress divergence due to the disturbance vibrationand to precisely perform gap control when feedback control is performedon the control actuator.

The MEMS driving device according to the aspect may further include abase substrate to which a part of the MEMS element is fixed, and thevibration detection unit may detect vibration of the MEMS element withregard to the base substrate.

According to the aspect, the MEMS element is fixed to the basesubstrate, and detects the vibration of a MEMS substrate with regard tothe base substrate. In this case, in addition to the disturbancevibration, which is added to the MEMS element from the outside, it ispossible to detect influence of substrate vibration which is generatedwhen the electrostatic actuator is driven in the MEMS element and tosuppress the influence due to the vibration.

In the MEMS driving device according to the aspect, an end of at leastone of the pair of substrates may be fixed to the base substrate, andthe vibration detection unit may detect vibration at a free end on aside which is opposite to the end of the substrate.

According to the aspect, an end of the substrate of the MEMS element isfixed to the base substrate, and the vibration detection unit detectsthe vibration of the free end side which is opposite to the fixed end.In this configuration, the vibration of the free end, which is farthestfrom the fixed part and in which vibration amplitude is large, isdetected, and thus it is possible to improve vibration detectionprecision. In addition, only a part of the substrate of the MEMS elementis fixed to the base substrate, and thus it is possible to suppress thedeflection of the substrate due to the difference in thermal expansioncoefficients between a fixed member, which fixes the substrate and thebase substrate, and the substrate.

In the MEMS driving device according to the aspect, at least one of thepair of substrates may include a first electrode which faces the basesubstrate, the base substrate may include a second electrode which facesthe first electrode, and the vibration detection unit may detect thevibration based on an electrostatic capacity between the first electrodeand the second electrode.

According to the aspect, the vibration detection unit detects thevibration based on the electrostatic capacity between the firstelectrode, which is provided on the substrate side of the MEMS element,and the second electrode which is provided on the base substrate. Withthis configuration, it is possible to simplify a configuration forvibration detection, compared to, for example, a configuration in whichvibration is detected using an optical sensor, a gyro sensor, or thelike.

In the MEMS driving device according to the aspect, the MEMS element maybe a wavelength variable interference filter that includes reflectionfilms which are provided on surfaces of the pair of substrates facingeach other, and that selects and emits light having a prescribedwavelength from incident light which is incident to the pair ofreflection films facing each other.

According to the aspect, the MEMS element is the wavelength variableinterference filter (wavelength variable-side Fabry-Perot etalon) thatincludes a pair of reflection films and that is capable of changing agap between the reflection films using the electrostatic actuator. Inthe wavelength variable interference filter, it is necessary to controlthe gap dimension between the pair of reflection films (the gapdimension between the pair of substrates) in nanometer order. When beingaffected by the disturbance vibration, the gap dimension fluctuates, andthus the wavelength of light, which is emitted, easily fluctuates. Incontrast, similarly to the above aspect, when the feed-forward voltagebased on the vibration, which is detected by the vibration detectionunit, is applied to the electrostatic actuator, it is possible tocontrol the gap precision between the reflection films of the wavelengthvariable interference filter with high precision, and thus it ispossible to suppress the fluctuation in the gap dimension due to thedisturbance vibration.

According to another aspect of the invention, there is provided anelectronic apparatus including: an MEMS driving device including an MEMSelement that includes a pair of substrates and an electrostatic actuatorwhich changes a gap dimension between the pair of substrates, avibration detection unit that detects vibration which is added to theMEMS element, and an actuator control unit that applies a feed-forwardvoltage based on a detected value of the vibration detection unit to theelectrostatic actuator; and a control unit that controls the MEMSdriving device.

According to the aspect, the disturbance vibration, which is added tothe MEMS element, is detected by the vibration detection unit, and thefeed-forward voltage is applied to the electrostatic actuator based onthe detected value such that the vibration is suppressed. Therefore,similarly to the above aspect, it is possible to suppress thefluctuation in the gap dimension between the pair of substrates due tothe vibration of the MEMS element, and thus it is possible to performdriving control on the MEMS element with high precision when thedisturbance vibration is added thereto. Therefore, it is possible tocause the fluctuation in the gap dimension between the pair ofsubstrates to more rapidly converge on the desired value. That is, it ispossible to rapidly change the MEMS element to a desired state, and thusit is possible to more rapidly perform a process in the electronicapparatus which includes the MEMS driving device.

In the MEMS driving method according to the aspect, there is provided anMEMS driving method which drives an MEMS element that includes a pair ofsubstrates and an electrostatic actuator which changes a gap dimensionbetween the pair of substrates, the MEMS driving method including:detecting vibration which is added to the MEMS element; and applying afeed-forward voltage based on the detected vibration to theelectrostatic actuator.

According to the aspect, the vibration detection unit detects thevibration which is added to the MEMS element, and applies thefeed-forward voltage, which is set according to the detected vibration,to the electrostatic actuator. Therefore, similarly to theabove-described aspect, it is possible to suppress the disturbance ofthe driving control in the MEMS driving device due to the vibration, andthus it is possible to realize driving with high precision.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will be described with reference to the accompanyingdrawings, wherein like numbers reference like elements.

FIG. 1 is a block diagram illustrating the schematic configuration of aspectroscopic measurement apparatus according to a first embodiment ofthe invention.

FIG. 2 is a block diagram illustrating the schematic configuration of anoptical module according to the first embodiment.

FIG. 3 is a sectional diagram illustrating the schematic configurationof an optical filter device according to the first embodiment.

FIG. 4 is a flowchart illustrating a method of driving the opticalmodule according to the first embodiment.

FIG. 5 is a block diagram illustrating the schematic configuration of anoptical module according to a second embodiment of the invention.

FIG. 6 is a sectional diagram illustrating the schematic configurationof the optical filter device according to the second embodiment.

FIG. 7 is a sectional diagram illustrating the schematic configurationof an optical filter device according to another embodiment.

FIG. 8 is a schematic diagram illustrating a colorimetric apparatuswhich is an example of an electronic apparatus according to theinvention.

FIG. 9 is a schematic diagram illustrating a gas detection apparatuswhich is an example of the electronic apparatus according to theinvention.

FIG. 10 is a block diagram illustrating the configuration of the controlsystem of the gas detection apparatus of FIG. 9.

FIG. 11 is a diagram illustrating the schematic configuration of a foodanalysis apparatus which is an example of the electronic apparatusaccording to the invention.

FIG. 12 is a diagram illustrating the schematic configuration of aspectroscopic camera which is an example of the electronic apparatusaccording to the invention.

DESCRIPTION OF EXEMPLARY EMBODIMENTS First Embodiment

Hereinafter, a first embodiment of the invention will be described withreference to the accompanying drawings.

Configuration of Spectroscopic Measurement Apparatus

FIG. 1 is a block diagram illustrating the schematic configuration of aspectroscopic measurement apparatus according to the first embodiment ofthe invention.

The spectroscopic measurement apparatus 1 is an apparatus that analyzeslight intensity having a prescribed wavelength in measurement targetlight which is reflected in a measurement target X, and measures anoptical spectrum thereof. Meanwhile, in the embodiment, an example isillustrated in which the measurement target light which is reflected inthe measurement target X is measured. However, when, for example, alight emitting material, such as a liquid crystal display, is used asthe measurement target X, light which is emitted from the light emittingmaterial may be used as the measurement target light.

As illustrated in FIG. 1, the spectroscopic measurement apparatus 1illustrates an optical module 10 which is an MEMS driving device of theinvention, a detector (detection unit), an I-V converter 12, anamplifier 13, an A/D convertor 14, and a control unit 20. In addition,the optical module 10 includes an optical filter device 6 and a filtercontrol unit 15.

The detector 11 receives light which passes through the wavelengthvariable interference filter 5 of the optical module 10, and outputs adetection signal (current) according to the light intensity of thereceived light.

The I-V converter 12 converts the detection signal, which is input fromthe detector 11, into a voltage value, and outputs a voltage to theamplifier 13.

The amplifier 13 amplifies the voltage (detection voltage), which isinput from the I-V converter 12, according to the detection signal.

The A/D convertor 14 converts the detection voltage (analog signal),which is input from the amplifier 13, into a digital signal, and outputsthe digital signal to the control unit 20.

The filter control unit 15 drives the wavelength variable interferencefilter 5 under the control of the control unit 20, and transmits lighthaving a prescribed objective wavelength from the wavelength variableinterference filter 5.

Configuration of Optical Module

Subsequently, the configuration of the optical module 10 will bedescribed below.

FIG. 2 is a block diagram illustrating the schematic configuration ofthe optical module 10.

As described above, the optical module 10 includes the optical filterdevice 6, inside which the wavelength variable interference filter 5 isstored, and the filter control unit 15.

Configuration of Optical Filter Device

FIG. 3 is an enlarged sectional diagram in which the optical filterdevice of FIG. 2 is enlarged. More specifically, FIG. 3 is a sectionaldiagram illustrating the optical filter device which is cut along thesubstrate thickness direction (normal directions of reflection films 54and 55 which will be described later).

The optical filter device 6 is a device which extracts light having theprescribed objective wavelength from incident light and emits theextracted light. As illustrated in FIGS. 2 and 3, the optical filterdevice 6 includes a housing 61, and the wavelength variable interferencefilter 5 which is stored inside the housing 61.

Configuration of Wavelength Variable Interference Filter

As illustrated in FIG. 3, the wavelength variable interference filter 5includes a fixed substrate 51, which is formed of a pair of substratesof the invention, and a movable substrate 52. The fixed substrate 51 andthe movable substrate 52 are formed of, for example, various types ofglasses, crystals, or the like, respectively. Further, as illustrated inFIG. 3, the substrates 51 and 52 are bonded together by a bonding film53, thereby being integrally formed.

As illustrated in FIG. 3, the fixed substrate 51 is provided with afixed reflection film 54 which forms one of a pair of reflection filmsof the invention. In addition, the movable substrate 52 is provided witha movable reflection film 55 which forms the other one of the pair ofreflection films of the invention. The fixed reflection film 54 andmovable reflection film 55 are arranged to face each other with a gap G1therebetween.

Further, the wavelength variable interference filter 5 is provided withan electrostatic actuator 56 which is used to adjust the distance of thegap G1 (gap dimension). The electrostatic actuator 56 includes a biaselectrostatic actuator 57 (hereinafter, referred to as a bias actuator57) and a control electrostatic actuator 58 (hereinafter, referred to asa control actuator 58) which are capable of being independently driven,respectively.

In addition, one end side of the fixed substrate 51 is provided with aprotruding part 514 which projects outward compared to the substrateedge of the movable substrate 52. In addition, one end side of themovable substrate 52, which is the opposite side of the protruding part514 of the fixed substrate 51, includes a protruding part which projectsoutward compared to the substrate edge of the fixed substrate 51. Asurface of the protruding part of the movable substrate 51, which is onthe side of the fixed substrate 51, forms an electric part 524.

In the embodiment, an example is shown in which the gap G1 between thereflection films 54 and 55 is formed to be smaller than the gap betweenthe electrodes. However, the gap G1 may be formed to be greater than thegap between the electrodes based on, for example, a wavelength regionwhich is transmitted by the wavelength variable interference filter 5.

Meanwhile, in the description below, a planar view which is viewed fromthe substrate thickness direction of the fixed substrate 51 and themovable substrate 52, that is, a planar view, in which the wavelengthvariable interference filter 5 is viewed from the direction of thelamination of the fixed substrate 51, the bonding film 53, and themovable substrate 52, is called a filter planar view. In addition, thecentral point of the reflection films 54 and 55 is called a centralfilter point, and the axial line which passes through the central filterpoint is called a central filter axis O.

Configuration of Fixed Substrate

On the fixed substrate 51, an electrode placement groove 511 and areflection film installation section 512 are formed through etching. Thefixed substrate 51 is formed to have a thicker dimension than themovable substrate 52, and the fixed substrate 51 is not deflectedbecause of the electrostatic attraction force, which is generated when avoltage is applied to the electrostatic actuator 56, or due to theinternal stress of the fixed electrode 571, 581.

The electrode placement groove 511 is formed in an annular shapecentering on the central filter axis O of the fixed substrate 51 in thefilter planar view. The reflection film installation section 512 isformed to project to the side of the movable substrate 52 from thecentral part of the electrode placement groove 511 in the planar view.Electrodes, which form the electrostatic actuator 56, are placed on thegroove bottom surface of the electrode placement groove 511. Inaddition, the fixed reflection film 54 is placed on the projecting tipsurface of the reflection film installation section 512.

On the groove bottom surface of the electrode placement groove 511, afixed bias electrode 571, which forms the bias actuator 57, and a fixedcontrol electrode 581, which forms the control actuator 58, are placed.

The fixed bias electrode 571 is formed in a substantially arc shape tosurround the reflection film installation section 512 in the filterplanar view. The fixed bias electrode 571 is wired to the electric part524 of the movable substrate 52, and is connected to the bias drivingunit 152 of the filter control unit 15, which will be described later,from the electric part 524.

The fixed control electrode 581 is formed in a substantially arc shapeon the outside of the fixed bias electrode 571 in the filter planarview. The fixed control electrode 581 is wired to the electric part 524of the movable substrate 52, and is connected to the feedback controlunit 154 of the filter control unit 15, which will be described later,from the electric part 524.

The fixed reflection film 54 is formed on the projected end surface ofthe reflection film installation section 512. For example, it ispossible to use a metal film formed of Ag or a conductive alloy filmformed of Ag alloy as the fixed reflection film 54. In addition, forexample, a dielectric multilayer film, in which a high refractive layeris set to be TiO₂ and a low refractive layer is set to be Si O₂, may beused. In this case, a conductive alloy film is formed on the bottomlayer or the surface layer of the dielectric multilayer film, and thusit is possible to cause the fixed reflection film 54 to function as anelectrode.

Further, a fixed mirror electrode, which is not shown in the drawing, isconnected to the fixed reflection film 54. The fixed mirror electrode iswired to the electric part 524 of the movable substrate 52, and isconnected to the gap detection unit 153 of the filter control unit 15,which will be described later, from the electric part 524.

Meanwhile, in the embodiment, an example is shown in which the fixedbias electrode 571, the fixed control electrode 581, and the fixedmirror electrode are independently placed, respectively. However, theinvention is not limited thereto. For example, the fixed bias electrode571, the fixed control electrode 581, and the fixed mirror electrode maybe connected to each other as common electrodes. In this case, in thefilter control unit 15, the common electrodes are connected to theground and are set to have equal potential.

Configuration of Movable Substrate

The movable substrate 52 includes a movable part 521 in a circular shapecentering on the central filter axis O, and a holding part 522 which hasthe same axis as the movable part 521 and holds the movable part 521.

The movable part 521 is formed to have a thicker dimension than theholding part 522. The movable part 521 is formed to have a largerdiameter dimension than at least the circumferential diameter dimensionof the projected end surface of the reflection film installation section512 in the filter planar view. Further, a movable bias electrode 572, amovable control electrode 582, and a movable reflection film 55 areprovided in the movable part 521.

The movable bias electrode 572 faces the fixed bias electrode 571through a prescribed gap. The movable bias electrode 572 is wired to theelectric part 524 of the movable substrate 52, and is connected to thebias driving unit 152 of the filter control unit 15, which will bedescribed later, from the electric part 524.

The movable control electrode 582 faces the fixed control electrode 581through the prescribed gap. The movable control electrode 582 is wiredto the electric part 524 of the movable substrate 52, and is connectedto the feedback control unit 154 of the filter control unit 15, whichwill be described later, from the electric part 524.

The movable reflection film 55 is provided to face the fixed reflectionfilm 54 through the gap G1 on the surface of the movable part 521 whichfaces the fixed substrate 51. A reflection film, which has the sameconfiguration as the above-described fixed reflection film 54, is usedas the movable reflection film 55.

Further, a fixed mirror electrode, which is not shown in the drawing, isconnected to the movable reflection film 55. The movable mirrorelectrode is wired to the electric part 524 of the movable substrate 52,and is connected to the gap detection unit 153 of the filter controlunit 15, which will be described later, from the electric part 524.

The holding part 522 is a diaphragm which surrounds the periphery of themovable part 521, and is formed to have a smaller thickness dimensionthan the movable part 521. The holding part 522 is more easily deflectedcompared to the movable part 521, and thus it is possible to displacethe movable part 521 to the side of the fixed substrate 51 due to slightelectrostatic attraction force. Here, the movable part 521 has thelarger thickness dimension and is harder than the holding part 522.Therefore, when the holding part 522 is pulled to the side of the fixedsubstrate 51 due to the electrostatic attraction force, the shape of themovable part 521 is not changed. Therefore, the movable reflection film55, which is provided at the movable part 521, is not deflected, andthus it is usually possible to maintain the fixed reflection film 54 andthe movable reflection film 55 in a parallel state.

Meanwhile, in the embodiment, the holding part 522 in thediaphragm-shape is described as an example. However, the invention isnot limited thereto. For example, a beam-shaped holding part, which isplaced at an equal angle interval centering on the central filter axisO, may be provided.

Configuration of Housing

The configuration of the housing 61 of the optical filter device 6 willbe described in detail.

As illustrated in FIG. 3, the housing 61 includes a base 62 (basesubstrate) and a lid 63. With regard to the base 62 and the lid 63, itis possible to use, for example, low melting point glass bonding usingglass frit (low-melting point glass), which is pieces of glass acquiredby melting a glass material at high temperature and rapidly cooling theglass material, bonding using epoxy resin, or the like. Therefore,accommodation space is formed inside, and the wavelength variableinterference filter 5 is stored in the accommodation space.

Configuration of Base

The base 62 is formed by laminating, for example, thin plate shapeceramics, and includes a pedestal part 621 and a side wall part 622.

The pedestal part 621 is formed in, for example, a flat plate shapewhich has a rectangular outer shape in the filter planar view. The sidewall part 622, which has a cylindrical shape, rises toward the lid 63from the periphery of the pedestal part 621. Meanwhile, in theembodiment, since the pedestal part 621 has a rectangular flat plateshape, an example is shown in which the side wall part 622 is formed ina square cylindrical shape. However, the side wall part 622 may beformed in, for example, a cylindrical shape.

The pedestal part 621 includes a light passage hole 623 which passestherethrough in the thickness direction. The light passage hole 623 isprovided to include an area which overlaps with the reflection films 54and 55 in a state in which the wavelength variable interference filter 5is accommodated in the pedestal part 621 in the planar view in which thepedestal part 621 is viewed from the thickness direction.

In addition, a cover glass 627, which is a light transmitting member ofthe invention for covering the light passage hole 623, is bonded to thesurface (outward base surface 621B) of the pedestal part 621 which is ona side opposite to the lid 63.

It is possible to bond the pedestal part 621 to the cover glass 627using, for example, the low melting point glass bonding, bonding usingan adhesive, or the like. In the embodiment, in a state in which insideof the accommodation space is maintained under decompression, anair-tight state is maintained. Therefore, it is preferable that thepedestal part 621 be bonded to the cover glass 627 using the low meltingpoint glass bonding.

In addition, on the inner surface of the pedestal part 621 which facesthe lid 63 (base inner surface 621A), the respective electrodes (thefixed bias electrode 571, the movable bias electrode 572, the fixedcontrol electrode 581, and the movable control electrode 582), which aredrawn to the electric part 524 of the wavelength variable interferencefilter 5, and an inner terminal part 624, which is connected to therespective mirror electrodes connected to the respective reflectionfilms 54 and 55, are provided. The inner terminal part 624 is connectedto the electrodes using, for example, a wire formed of Au through wirebonding. Meanwhile, in the embodiment, the wire bonding is described asan example. However, for example, Flexible Printed Circuits (FPC) or thelike may be used.

In addition, a conductive hole 625 is formed in a location, in which theinner terminal part 624 is provided, at the pedestal part 621. The innerterminal part 624 is connected to an outward terminal part 626, which isprovided on the outward base surface 621B of the pedestal part 621,through the conductive hole 625. The outward terminal part 626 iselectrically connected to the filter control unit 15.

The side wall part 622 rises from the edge of the pedestal part 621, andcovers the periphery of the wavelength variable interference filter 5which is mounted on an inner base surface 621A. A surface of the sidewall part 622, which faces the lid 63 is, for example, a flat surfacewhich is parallel to the inner base surface 621A.

Further, the wavelength variable interference filter 5 is fixed to thebase 62 using, for example, a fixing member 64 such as an adhesive.Here, the wavelength variable interference filter 5 may be fixed to thepedestal part 621 or may be fixed to the side wall part 622. A location,in which the fixing member 64 is provided, may include a plurality ofplaces. However, in order to suppress the stress of the fixing member 64from being transmitted to the wavelength variable interference filter 5,it is preferable that the wavelength variable interference filter 5 isfixed in a single place. In the embodiment, an example is shown in whicha part of the surface of the movable substrate 52, which is on a sideopposite to the fixed substrate 51, is fixed to the pedestal part 621 onthe side of the electric part 524 of the movable substrate 52, asillustrated in FIG. 3.

Configuration of Lid

The lid 63 is a flat glass plate, and is bonded to the cross section ofthe side wall part 622 of the base 62. As described above, it ispossible to use the low melting point glass bonding or the like as amethod of bonding the lid 63 to the base 62.

Configuration of Filter Control Unit

As illustrated in FIG. 2, the filter control unit includes the vibrationdisturbance detection unit 151, the bias driving unit 152, the gapdetection unit 153, the feedback control unit 154, and themicro-computer (micro-controller) 16.

The vibration disturbance detection unit 151 is a vibration detectionunit of the invention, and detects the disturbance vibration, which isadded to the optical filter device 6, from the outside. Morespecifically, the vibration disturbance detection unit 151 is formed of,for example, various types of sensors such as a gyro sensor and anacceleration sensor, and detects the disturbance vibration, which isadded to the optical filter device 6, from the quantity of a state, suchas acceleration, which is detected by the sensors. In addition, thevibration disturbance detection unit 151 outputs the detected value ofthe detected disturbance vibration to the bias driving unit 152.

When the control actuator 58 performs control, the bias driving unit 152applies a bias voltage to the bias actuator 57 such that sensitivitybecomes uniform. In addition, the bias driving unit 152 is formed toinclude a feed-forward control unit 152A, and applies the bias voltagesuch that the disturbance vibration is offset according to thedisturbance vibration, which is added to the optical filter device 6.That is, the bias driving unit 152 forms an actuator control unit in theinvention. More specifically, the feed-forward control unit 152A adjuststhe bias voltage by adding or subtracting a prescribed value based onthe detected value of the disturbance vibration, which is input from thevibration disturbance detection unit 151, to or from a bias instructionvalue which is input from the micro-computer 16.

The gap detection unit 153 detects the dimension of the gap G1 from theelectrostatic capacity between the reflection films 54 and 55, andoutputs a detection signal to the feedback control unit 154. Morespecifically, the gap detection unit 153 includes a C-V convertingcircuit, which is not shown in the drawing, and converts theelectrostatic capacity between the reflection films 54 and 55 into avoltage value (detection signal). For example, a switched capacitorcircuit or the like may be provided as an example of the C-V convertingcircuit.

Meanwhile, the gap detection unit 153 may output an analog signal or adigital signal as the detection signal. When the digital signal isoutput, the detection signal (analog signal) from the C-V convertingcircuit is input to an Analog to Digital Converter (ADC) and isconverted into a digital value.

The feedback control unit 154 applies the feed-back voltage to thecontrol actuator 58 based on an instruction signal, in which the gap G1input from the micro-computer 16 is set to a prescribed objective value,and the detected value which is input from the gap detection unit 153.

The micro-computer 16 includes a memory 161, and stores, for example,the relationship (gap correlative data) between the detection signal(voltage signal), which is detected by the gap detection unit 153, andthe dimension of the gap G1.

In addition, as illustrated in FIG. 2, the micro-computer 16 functionsas a bias instruction section 162 and an objective instruction section163.

When a wavelength setting instruction is input from the control unit 20,the bias instruction section 162 calculates the bias voltagecorresponding to an objective wavelength, and outputs the bias voltageto the bias driving unit 152.

When the wavelength setting instruction is input from the control unit20, the objective instruction section 163 calculates the dimension ofthe gap G1 (objective value) corresponding to the objective wavelength,and outputs the dimension of the gap G1 to the feedback control unit 154as an objective signal.

Configuration of Control Unit

Returning to FIG. 1, the control unit 20 of the spectroscopicmeasurement apparatus 1 will be described.

The control unit 20 corresponds to the processing unit of the invention,is configured in a manner in which, for example, a CPU, a memory, andthe like are combined, and controls the entire operation of thespectroscopic measurement apparatus 1. As illustrated in FIG. 1, thecontrol unit 20 includes a wavelength setting unit 21, a light quantityacquisition unit 22, a spectrum measurement unit 23, and a storage unit30.

The storage unit 30 stores various types of programs for controlling thespectroscopic measurement apparatus 1, and various types of data (forexample, V-λ data which indicates a driving voltage for an objectivewavelength).

The wavelength setting unit 21 sets the objective wavelength of lightwhich is extracted by the wavelength variable interference filter 5, andoutputs a control signal, which indicates that the set objectivewavelength is extracted from the wavelength variable interference filter5, to the filter control unit 15.

The light quantity acquisition unit 22 acquires the quantity of light,which passes through the wavelength variable interference filter 5 andwhich has the objective wavelength, based on the quantity of light whichis acquired by the detector 11.

The spectrum measurement unit 23 measures the spectral characteristicsof the measurement target light based on the quantity of light which isacquired by the light quantity acquisition unit 22.

Method for Driving Wavelength Variable Interference Filter

FIG. 4 is a flowchart illustrating a method (actuator control method) ofdriving the wavelength variable interference filter in a spectroscopicmeasurement process of the spectroscopic measurement apparatus 1.

In order to acquire the intensity of light of each wavelength includedin the measurement target light using the spectroscopic measurementapparatus 1, first, the control unit 20 sets the wavelength (objectivewavelength) of light, which passes through the wavelength variableinterference filter 5, using the wavelength setting unit 21. Further,the wavelength setting unit 21 outputs the wavelength settinginstruction, through which light having the set objective wavelengthpasses, to the filter control unit 15 (step S1).

Subsequently, the bias instruction section 162 of the micro-computer 16sets a provisional bias voltage corresponding to the objectivewavelength which is designated by the wavelength setting instruction(step S2).

More specifically, the bias instruction section 162 sets the provisionalbias voltage such that sensitivity (gap displacement (m/V) for anapplied voltage), which is acquired when a voltage is applied to thecontrol actuator 58, is uniform in feedback control.

Here, the sensitivity RC (m/V), which is acquired when a voltage isapplied to the control actuator 58, is expressed in Equation 1 below.

$\begin{matrix}{R_{C} = \frac{\left\{ {{2\; k\; ɛ\; S_{C}{d\left( {d_{\max} - d} \right)}^{2}} - {ɛ^{2}S_{C}S_{b}V_{b}^{2}}} \right\}^{1/2}}{{k\left( {d_{\max} - d} \right)}\left( {d_{\max} - {3d}} \right)}} & (1)\end{matrix}$

In Equation 1, V_(b) indicates the provisional bias voltage which isapplied to the bias actuator 57, k indicates the spring coefficient ofthe movable substrate 52 (holding part 522), ∈ indicates thepermittivity between the fixed substrate 51 and the movable substrate 52(the gap between the electrodes), S_(b) indicates the effective area ofthe bias actuator 57, S_(c) indicates the effective area of the controlactuator 58, dmax indicates the initial amount of the gap between theelectrodes, and d indicates the objective displacement of the movablepart 521 (the displacement of the gap between the electrodes) which isused to cause light having the objective wavelength to passtherethrough.

In Equation 1, RC is a uniform value and a value, which is set inadvance according to a fixed gain in a controller included in thefeedback control unit 154 is used. In addition, when the wavelengthsetting instruction, in which the objective wavelength is designated, isinput from the control unit 20, the micro-computer 16 can calculate theobjective value of the gap G1 which is necessary to extract light havingthe objective wavelength from the wavelength variable interferencefilter 5, and can calculate an amount which displaces the movable part521 (objective displacement d) from the objective value.

When Equation 1 is solved with regard to V_(b), it is possible to derivesubsequent Equation 2.

$\begin{matrix}{V_{b} = \left\lbrack {\frac{k}{ɛ\; S_{b}}\left\{ {{2{d\left( {d_{\max} - d} \right)}^{2}} - \frac{{{kR}_{c}^{2}\left( {d_{\max} - d} \right)}^{2}\left( {d_{\max} - {3d}} \right)^{2}}{ɛ\; S_{c}}} \right\}} \right\rbrack^{1/2}} & (2)\end{matrix}$

Subsequently, the filter control unit 15 performs feed-forward controlthrough the bias driving unit 152 and feedback control through thefeedback control unit 154, that is, performs voltage control on theelectrostatic actuator of the wavelength variable interference filter 5(step S3).

More specifically, the bias instruction section 162 calculates theprovisional bias voltage V_(b) based on the above-described Equation 2,and outputs a bias instruction to the bias driving unit 152.

When the bias driving unit 152 acquires a bias instruction value fromthe micro-computer 16, the bias driving unit 152 sets a bias voltage,which is applied as a feed-forward voltage, from the provisional biasvoltage V_(b) based on the vibration detected value, which is input fromthe vibration disturbance detection unit 151, and applies the set biasvoltage to the bias actuator 57.

The feed-forward voltage is a voltage which is used to offset thedisturbance vibration, and the feed-forward control unit 152A calculatesthe feed-forward voltage by adding and subtracting a prescribed value,which is set in advance for the detected value from the vibrationdisturbance detection unit 151, to and from the provisional bias voltageV_(b) which is calculated using Equation 2.

Therefore, for example, when high-frequency disturbance vibration isadded to the optical filter device 6, electrostatic attraction force isgiven by the bias actuator 57 such that the influence of the disturbancevibration is offset.

In addition, the feedback control is performed by the feedback controlunit 154.

That is, the feedback control unit 154 calculates the deviation betweenthe detection signal, which is input from the gap detection unit 153,and the objective instruction signal, which is input from themicro-computer 16, and applies the feed-back voltage to the controlactuator 58 such that the difference therebetween is “0”. Here, thefeed-forward voltage (bias voltage) is usually applied as describedabove, and thus the vibration of the movable part 521 due to thedisturbance vibration is suppressed. Therefore, when the feedbackcontrol is performed, it is possible to precisely and rapidly put thedimension of the gap G1 into a desired objective value without vibrationand divergence of the movable part 521 occurring due to the disturbancevibration.

Using the driving control process as described above, light having theobjective wavelength is emitted from the wavelength variableinterference filter 5 and is received by the detector 11. Further, thelight quantity acquisition unit 22 of the control unit 20 acquires thequantity of light having the objective wavelength based on the inputsignal from the detector 11.

Further, when the above-described driving control process issequentially performed by converting the objective wavelength, it ispossible to acquire the quantity of light having a plurality ofwavelengths which are necessary for spectrometry. Therefore, thespectrum measurement unit 23 can perform the spectroscopic measurementprocess on a measurement target based on the acquired quantity of lighthaving each of the objective wavelengths.

Operational Effect of First Embodiment

The optical module 10 of the spectroscopic measurement apparatus 1according to the embodiment includes the optical filter device 6 and thefilter control unit 15. In addition, the optical filter device 6includes the pair of substrates 51 and 52, and the wavelength variableinterference filter 5 that includes the electrostatic actuator 56 whichcontrols the gap dimension between the substrates 51 and 52. Thewavelength variable interference filter 5 is stored inside the housing61. Further, the filter control unit 15 includes the vibrationdisturbance detection unit 151 that detects the disturbance vibration,and outputs the vibration detected value, which is detected by thevibration disturbance detection unit 151, to the bias driving unit 152.The bias driving unit 152 applies the feed-forward voltage based on thevibration detected value to the bias actuator 57 which is included inthe electrostatic actuator 56.

Therefore, in the embodiment, when the disturbance vibration is added,the feed-forward voltage is applied to the bias actuator 57, and thus itis possible to operate the electrostatic attraction force such that thevibration of the movable part 521 due to the disturbance vibration issuppressed. Accordingly, the vibration of the movable part 521 due tothe influence of the disturbance vibration is suppressed, and thus it ispossible to precisely perform gap control when the feedback control isperformed. That is, it is possible to cause the fluctuation in the gapdimension between the reflection films 54 and 55 to further rapidlyconverge, and it is possible to reduce an amount of time from when theelectrostatic actuator 56 starts to be driven to when light having theobjective wavelength is emitted from the wavelength variableinterference filter 5. Therefore, it is possible to rapidly perform thespectroscopic measurement process in the spectroscopic measurementapparatus 1.

In the embodiment, the electrostatic actuator 56 includes the biasactuator 57 and the control actuator 58, and the feed-forward voltageaccording to the disturbance vibration, which is detected by thevibration disturbance detection unit 151, is applied to the biasactuator 57.

The control actuator 58 is an actuator which is used to perform thefeedback control according to the gap dimension between the reflectionfilms 54 and 55, and it is difficult to perform the feedback controlwhen the sensitivity of the electrostatic actuator changes. In contrast,the bias actuator 57 is an actuator which is used to uniformly maintainthe sensitivity of the control actuator 58 when the feedback control isperformed, and can function as a coarse adjustment driving actuator.When the feed-forward voltage corresponding to the disturbance vibrationis applied to the bias actuator, it is possible to suppress the changein the sensitivity of the control actuator 58 when the feedback controlis performed, and thus it is possible to perform the appropriate gapcontrol.

In the embodiment, the vibration disturbance detection unit 151 includesthe sensor which detects the management state of the optical filterdevice 6, such as an acceleration sensor or a gyro sensor. Therefore, itis possible to easily determine the vibration state of the opticalfilter device 6, the magnitude of the vibration, and the like. Inaddition, there are many cases in which the acceleration sensor or thegyro sensor is normally provided in, for example, a mobile terminalapparatus, such as a smart phone or a tablet terminal, which includes animaging apparatus. Therefore, it is possible to detect the disturbancevibration which is added to the optical filter device 6 by mounting theoptical filter device 6 on, for example, the mobile terminal apparatusand causing a mobile terminal apparatus-side sensor to function as thevibration detection unit.

In the embodiment, the feed-forward control unit 152A sets thefeed-forward voltage (bias voltage) by adding and subtracting aprescribed value, which is set in advance according to the vibrationdetected value of the disturbance vibration, to and from the provisionalbias voltage. It is possible to easily acquire the prescribed value bystoring the prescribed value in, for example, a memory or the like astable data, and it is possible to easily calculate the feed-forwardvoltage which is used to suppress vibration.

Second Embodiment

Subsequently, a second embodiment of the invention will be describedwith reference to the accompanying drawings.

In the first embodiment, the disturbance vibration is detected by thevibration disturbance detection unit 151 using the gyro sensor, theacceleration sensor, or the like, and the feed-forward voltage (biasvoltage) is applied to the bias actuator 57 according to the detectedvalue. In contrast, the second embodiment is different from the firstembodiment in that the vibration of the wavelength variable interferencefilter 5 is detected with regard to the optical filter device 6.

FIG. 5 is a block diagram illustrating the schematic configuration ofthe optical module 10 according to the second embodiment.

FIG. 6 is a sectional diagram illustrating the schematic configurationof an optical filter device 6A according to the second embodiment.

In the embodiment, a filter-side capacity electrode 515, which is thefirst electrode of the invention, is provided on a surface of theprotruding part 514 of the fixed substrate 51 of the wavelength variableinterference filter 5, which faces the pedestal part 621, as illustratedin FIG. 6. That is, in the wavelength variable interference filter 5,the filter-side capacity electrode 515 is provided at the protrudingpart 514 which is on an opposite side end of one end which is fixed bythe fixing member 64.

In addition, a base-side capacity electrode 628, which is the secondelectrode of the invention, is provided to face the filter-side capacityelectrode 515 at the pedestal part 621 of the base 62, as illustrated inFIG. 6. The filter-side capacity electrode 515 and the base-sidecapacity electrode 628 are respectively connected to the second gapdetection unit 155 in the filter control unit 15A, as illustrated inFIG. 5.

Further, the second gap detection unit 155 detects the change in theelectrostatic capacity of the filter-side capacity electrode 515 and thebase-side capacity electrode 628. That is, the second gap detection unit155 detects the vibration state of the wavelength variable interferencefilter 5 with regard to the housing 61, and the filter-side capacityelectrode 515, the base-side capacity electrode 628, and the second gapdetection unit 155 form the vibration detection unit of the invention.Further, the second gap detection unit 155 outputs a voltage signal inaccordance with the change in electrostatic capacity to the bias drivingunit 152.

In the embodiment which is configured as described above, in step S3 ofFIG. 4, the bias driving unit 152 calculates and applies thefeed-forward voltage, which is used to offset the vibration of thewavelength variable interference filter 5, based on the voltage signalwhich is input from the second gap detection unit 155 with regard to theprovisional bias voltage which is calculated based on theabove-described Equation 2. That is, the feed-forward control unit 152Acalculates the feed-forward voltage by adding and subtracting theprescribed value, which is set in advance to the voltage signal from thesecond gap detection unit 155, to and from the provisional bias voltage,and applies the feed-forward voltage to the bias actuator 57 as the biasvoltage.

In the configuration of the embodiment as described above, the secondgap detection unit 155 detects the change in the electrostatic capacityof the filter-side capacity electrode 515 and the base-side capacityelectrode 628. Therefore, it is possible to directly detect thevibration of the wavelength variable interference filter 5 with regardto the housing 61. In this case, in addition to the disturbancevibration, which is added to the optical filter device 6 from theoutside, it is possible to detect the vibration of the wavelengthvariable interference filter 5 due to the vibration of the movable part521 which is generated when the electrostatic actuator 56 is driven.That is, when there is no disturbance vibration, there is a case inwhich the movable part 521 vibrates because the electrostatic actuator56 is driven and the wavelength variable interference filter 5 vibrateswith regard to the housing 61 due to the influence of the vibration. Inthe embodiment, it is possible to precisely detect such vibration.Therefore, when the bias driving unit 152 applies the bias voltage tothe bias actuator 57 such that the disturbance vibration and thevibration, which is generated because the electrostatic actuator 56 isdriven, are offset, it is possible to perform more precise gap control,and thus it is possible to advance the convergence of vibration when theelectrostatic actuator 56 is driven. Accordingly, it is possible tofurther rapidly measure the quantity of light having a desiredwavelength, and thus it is possible to rapidly perform a measurementprocess in the spectroscopic measurement process of the spectroscopicmeasurement apparatus 1.

In the embodiment, the side of the electric part 524 of the wavelengthvariable interference filter 5 is fixed to the base 62, and thefilter-side capacity electrode 515 is provided at the protruding part514 which is on a free end side on the opposite side of the fixed end.

That is, in the embodiment, the vibration state of the free end side,which is farthest from the fixed end and in which the amplitude is largein a case of vibration, is detected. Therefore, it is possible tosecurely detect the vibration of the wavelength variable interferencefilter 5 and to suppress the influence of the vibration.

In the embodiment, the filter-side capacity electrode 515 and thebase-side capacity electrode 628 are included as the vibration detectionunit of the invention. Therefore, the electrostatic capacity between apair of electrodes which face each other is detected by the second gapdetection unit 155, and thus it is possible to precisely detect thevibration of the wavelength variable interference filter 5 with a simpleconfiguration.

Other Embodiments

Meanwhile, the invention is not limited to the above-describedembodiments, and modifications, improvements, and the like thereofwithin a range, in which it is possible to accomplish the object of theinvention, may be included in the invention.

For example, in the second embodiment, an example is shown in which thesecond gap detection unit 155 detects the change in the electrostaticcapacity between the filter-side capacity electrode 515, which isprovided on the surface of the protruding part 514 on the side of themovable substrate 52, and the base-side capacity electrode 628. However,the invention is not limited thereto. For example, an optical filterdevice 6B, as illustrated in FIG. 7, may be used.

That is, a filter-side capacity electrode 515A may be provided on a sideend surface of the protruding part 514, which is perpendicular to asurface in which the fixed substrate 51 and the movable substrate 52face each other, and a base-side capacity electrode 628A may be providedin a region which faces the filter-side capacity electrode 515A. Thefilter-side capacity electrode 515A and the base-side capacity electrode628A are provided having the same shape and the same size. When thewavelength variable interference filter 5A vibrates, the area betweenthe electrodes, which face each other, changes, and thus theelectrostatic capacity changes.

In the second embodiment, the gap dimension between the electrodes 515and 628 fluctuates with regard to the vibration of the wavelengthvariable interference filter 5, and thus the change in the electrostaticcapacity is non-linear due to the vibration. In contrast, in theconfiguration as illustrated in FIG. 7, the fluctuation in the gapdimension between the electrodes 515A and 628A due to the vibration isextremely small, and the change in the electrostatic capacity is linear.Therefore, it is possible to precisely detect the vibration state of thewavelength variable interference filter 5, and it is possible to moreprecisely set the bias voltage in order to offset the vibration.

In the second embodiment, an example is shown in which the filter-sidecapacity electrode 515 is provided at the protruding part 514 of thefixed substrate 51. However, the invention is not limited thereto. Forexample, when the protruding part 514 of the wavelength variableinterference filter 5 is fixed to the base 62, the filter-side capacityelectrode may be provided on the protruding part side of the movablesubstrate 52, which is the free end, and the base-side capacityelectrode may be provided in an area which faces the filter-sidecapacity electrode of the base 62.

In addition, an example is shown in which the filter-side capacityelectrode is provided at the free end on the opposite side of the fixedpart of the base 62 of the wavelength variable interference filter 5.However, the filter-side capacity electrode may be provided in an areaother than the fixed part of the base 62 of the wavelength variableinterference filter 5. For example, the filter-side capacity electrodemay be provided in the intermediate location between the fixed part ofthe base 62 of the wavelength variable interference filter 5 and thefree end which is farthest from the fixed part, and the base-sidecapacity electrode may be provided to face the filter-side capacityelectrode.

In addition, the base-side capacity electrode is provided on the base62. However, the invention is not limited thereto. If an area faces thefilter-side capacity electrode, a capacity electrode corresponding toany location within the housing 61 may be provided. For example, afilter-side capacity electrode may be provided on a side (surface whichfaces the lid 63) of the protruding part 514 which is opposite to themovable substrate 52, and a lid-side capacity electrode, which is thesecond electrode of the invention, may be provided at a part of the lid63 which faces the filter-side capacity electrode.

Further, the filter-side capacity electrode and a housing-side capacityelectrode, which faces the filter-side capacity electrode, may beprovided in plural.

In the second embodiment, an example is shown in which the vibrationstate is detected based on the change in the electrostatic capacitybetween the electrodes 515 and 628. However, the invention is notlimited thereto. For example, in the filter planar view of thewavelength variable interference filter 5, a laser irradiation unitwhich irradiates laser light and a detection unit which detectsreflected laser light may be provided in locations which do not overlapwith the reflection films 54 and 55, and the vibration state of thewavelength variable interference filter 5 may be detected based on thelocations and intensity of the reflected laser light which is detectedin the detection unit.

In each of the above embodiments, the wavelength variable interferencefilter 5 is described as an example of the MEMS element. However, forexample, a wavelength fixing-side interference filter to which the gapdimension between the reflection films 54 and 55 is fixed may be used.When such an interference filter is used, there is a case in which thegap dimension between the reflection films fluctuates due to thedisturbance vibration. In this case, the wavelength of light which isemitted from the interference filter fluctuates. In contrast, when anelectrostatic actuator, which is capable of changing the distancebetween a pair of substrates of the interference filter, is placed andthe feed-forward voltage according to the vibration detected value,which is detected by a vibration detection unit (for example, thevibration disturbance detection unit 151, the second gap detection unit155, or the like) is applied to the electrostatic actuator, it ispossible to suppress the fluctuation in the gap dimension between thereflection films due to the disturbance vibration. In this case, unlikein the embodiments, it is not necessary to include two or moreactuators, such as the bias actuator 57 and the control actuator 58, asthe electrostatic actuator, and a single electrostatic actuator may beprovided.

In each of the above embodiments, the reflection films 54 and 55 areused as electrodes for capacity detection. However, the invention is notlimited thereto. For example, electrodes for capacity detection, whichface each other, may be provided on the fixed substrate 51 and themovable substrate 52, separately from the reflection films 54 and 55

In the embodiments, the optical module 10, which controls the driving ofthe wavelength variable interference filter 5, is described as anexample of the MEMS driving device. However, the invention is notlimited thereto.

For example, the MEMS driving device can be applied to any MEMS elementdriving device that includes a pair of substrates which face each otherand that changes the gap dimension between the pair of substrates. Assuch an apparatus, there is, for example, a mirror device or the like inwhich a mirror is placed on one side of the pair of substrates and whichchanges the direction of light reflected in the mirror by changing anangle with regard to a substrate (base substrate) that is another sideof the substrate (mirror substrate) on which the mirror is placed. Insuch a mirror device, for example, a plurality of electrostaticactuators are placed between the substrates and voltages applied to therespective electrostatic actuators are changed respectively, therebysetting an inclination angle of the mirror substrate to a desired angle.In this case, when the disturbance vibration or the vibration, generatedwhen the electrostatic actuator is driven, is added to the mirrordevice, it is difficult to control the gap dimension between substrates.In contrast, similarly to the embodiments, when the vibration detectionunit (for example, the vibration disturbance detection unit 151, thesecond gap detection unit 155, or the like) of the invention is providedand vibration is offset by applying the feed-forward voltagecorresponding to the detected vibration to the electrostatic actuator,it is possible to perform highly precise gap control.

In addition, in each of the above embodiments, the spectroscopicmeasurement apparatus 1 is described as the electronic apparatus of theinvention. In addition to the spectroscopic measurement apparatus 1, itis possible to apply the wavelength variable interference filter drivingmethod, the optical module, and the electronic apparatus of theinvention in various fields.

For example, it is possible to apply the electronic apparatus of theinvention to a colorimetric apparatus which measures colors, as shown inFIG. 8.

FIG. 8 is a schematic diagram illustrating an example of a colorimetricapparatus 400 which includes a wavelength variable interference filter.

As shown in FIG. 8, the colorimetric apparatus 400 includes a lightsource device 410 which emits light to a test target A, a colorimetricsensor 420 (optical module), and a control device 430 (processing unit)which controls the entire operation of the colorimetric apparatus 400.Further, the colorimetric apparatus 400 is an apparatus that causeslight, which is emitted from the light source device 410, to bereflected in the test target A, receives reflected test target lightusing the colorimetric sensor 420, and analyzes and measures thechromaticity of the test target light, that is, the color or the testtarget A based on a detection signal which is output from thecolorimetric sensor 420.

The light source device 410 includes a light source 411 and a pluralityof lenses 412 (only one lens is illustrated in FIG. 8), and emits, forexample, reference light (for example, white light) to the test targetA. In addition, the plurality of lenses 412 may include a collimatorlens. In this case, the light source device 410 causes the referencelight, which is emitted from the light source 411, to be parallel lightusing the collimator lens, and emits the parallel light to the testtarget A from a projection lens which is not shown in the drawing.Further, in the embodiment, the colorimetric apparatus 400, whichincludes the light source device 410, is described. However, forexample, when the test target A is a light emitting member, such as aliquid crystal panel, the colorimetric apparatus 400 may not include thelight source device 410.

As illustrated in FIG. 8, the colorimetric sensor 420 includes anoptical filter device 6 in which the wavelength variable interferencefilter 5 is stored, a detector 11 which receives light passing throughthe wavelength variable interference filter 5, and a filter control unit15 which changes the wavelength of light passing through the wavelengthvariable interference filter 5. In addition, the colorimetric sensor 420includes an incident light optical lens, which is not shown in thedrawing and which guides reflected light (test target light) that isreflected in the test target A to the inside thereof, in a locationwhich faces the wavelength variable interference filter 5. Further, thecolorimetric sensor 420 spectrally separates light having a prescribedwavelength of the test target light, which is emitted from the incidentoptical lens, using the wavelength variable interference filter 5, andreceives the spectrally separated light using the detector 11. Further,the optical filter device 6A and the filter control unit 15A may beplaced instead of the optical filter device 6 and the filter controlunit 15.

The control device 430 controls the entire operation of the colorimetricapparatus 400.

It is possible to use, for example, a general-purpose personal computer,a mobile information terminal, and other dedicated colorimetriccomputers as the control device 430. Further, as shown in FIG. 8, thecontrol device 430 includes a light source control unit 431, acolorimetric sensor control unit 432, a colorimetric processing unit433, and the like.

The light source control unit 431 is connected to the light sourcedevice 410, outputs a prescribed control signal to the light sourcedevice 410 based on, for example, the setting input of a user, and emitswhite light having prescribed brightness.

The colorimetric sensor control unit 432 is connected to thecolorimetric sensor 420, sets the wavelength of light, which is receivedby the colorimetric sensor 420 based on, for example, the setting inputof the user, and outputs a control signal to detect the quantity oflight having the wavelength to the colorimetric sensor 420. The filtercontrol unit 15 of the colorimetric sensor 420 applies a voltage to theelectrostatic actuator 56 based on the control signal, and drives thewavelength variable interference filter 5.

The colorimetric processing unit 433 analyzes the chromaticity of thetest target A based on the quantity of received light which is detectedby the detector 11.

In addition, an optical-based system, which detects the presence of aspecified material, is described as another example of the electronicapparatus of the invention. As such a system, it is possible to use agas detection apparatus, such as a gas leak detector for a vehicle or anoptoacoustic noble gas detector for expiration test, which highlysensitively detects specified gas by a spectroscopic measurement methodusing, for example, the wavelength variable interference filter of theinvention.

An example of the gas detection apparatus will be described below withreference to the accompanying drawings.

FIG. 9 is a schematic diagram illustrating an example of the gasdetection apparatus using the wavelength variable interference filter.

FIG. 10 is a block diagram illustrating the configuration of the controlsystem of the gas detection apparatus of FIG. 9.

As illustrated in FIG. 9, the gas detection apparatus 100 includes asensor chip 110, a flow passage 120 which includes a suction port 120A,a suction flow passage 120B, a discharge flow passage 120C and adischarge port 120D, and a main body part 130.

The main body part 130 includes a detector (optical module) thatincludes a sensor part cover 131 which has an opening causing the flowpassage 120 to be detachable, a discharge section 133, a housing 134, anoptical part 135, a filter 136, an optical filter device 6 and a lightreceiving element 137 (detection unit), a control unit 138 (processingunit) that processes a detected signal and controls the detection unit,a power supply unit 139 that supplies power, and the like. In addition,the optical part 135 includes a light source 135A which emits light, abeam splitter 135B which reflects light incident from the light source135A in the side of the sensor chip 110 and causes light incident fromthe side of the sensor chip to pass through the side of the lightreceiving element 137, and lenses 135C, 135D, and 135E.

In addition, as illustrated in FIG. 10, an operation panel 140, adisplay unit 141, a connection unit 142 for interfacing with theoutside, and a power supply unit 139 are provided on the surface of thegas detection apparatus 100. When the power supply unit 139 is asecondary battery, a connection unit 143 for charging electricity may beprovided.

Further, as illustrated in FIG. 10, the control unit 138 of the gasdetection apparatus 100 includes a signal processing unit 144 which hasa CPU or the like, a light source driver circuit 145 which controls thelight source 135A, a filter control unit 15 which controls thewavelength variable interference filter 5, a light receiving circuit 147which receives a signal from the light receiving element 137, a sensorchip detection circuit 149 which reads the code of the sensor chip 110and receives a signal from a sensor chip detector 148 which detects thepresence or absence of the sensor chip 110, and a discharge drivercircuit 150 which controls the discharge section 133.

Subsequently, the operation of the above-described gas detectionapparatus 100 will be described below.

A sensor chip detector 148 is provided inside the sensor part cover 131which is at the upper part of the main body part 130, and the sensorchip detector 148 detects the presence or absence of the sensor chip110. When the signal processing unit 144 detects a detection signal fromthe sensor chip detector 148, the signal processing unit 144 determinesa state in which the sensor chip 110 is mounted, and outputs a displaysignal for displaying that it is possible to perform a detectionoperation to the display unit 141.

Further, for example, when the operation panel 140 is operated by a userand an instruction signal for starting a detection process is outputfrom the operation panel 140 to the signal processing unit 144, thesignal processing unit 144, first, operates the light source 135A byoutputting a light source operation signal to the light source drivercircuit 145. When the light source 135A is driven, laser light which hasa single wavelength and stable linear polarization is emitted from thelight source 135A. In addition, a temperature sensor and a lightquantity sensor are embedded in the light source 135A, and theinformation thereof is output to the signal processing unit 144.Further, when the signal processing unit 144 determines that the lightsource 135A is stably operated based on the temperature and the quantityof light input from the light source 135A, the signal processing unit144 controls the discharge driver circuit 150 such that the dischargesection 133 is operated. Therefore, a gas sample, which includes atarget substance (gas molecule) to be detected, is introduced from thesection port 120A to the suction flow passage 120B, inside the sensorchip 110, the discharge flow passage 120C, and the discharge port 120D.Meanwhile, in the section port 120A, a dust removing filter 120A1 isprovided to remove relatively large dust particles, some moisture, orthe like.

In addition, the sensor chip 110 is a sensor in which a plurality ofmetal nanostructures is incorporated and which uses localized surfaceplasmon resonance. In the sensor chip 110, a reinforcement electricfield is formed between the metal nanostructures due to laser light, andRaman-scattering light and Rayleigh-scattering light, which containinformation related to molecular vibration, are generated when the gasmolecule enters the reinforcement electric field.

The Rayleigh-scattering light and the Raman-scattering light areincident into the filter 136 through the optical part 135, theRayleigh-scattering light is separated by the filter 136, and thus theRaman-scattering light is incident into the wavelength variableinterference filter 5. Further, the signal processing unit 144 outputsthe control signal to the filter control unit 15. Therefore, similarlyto the first embodiment, in a state in which the feed-forward voltage(bias voltage) is applied to the bias actuator 57 such that thedisturbance vibration is suppressed, the filter control unit 15 appliesthe feed-back voltage to the control actuator 58 such that theRaman-scattering light corresponding to the gas molecule which is adetection target passes through the wavelength variable interferencefilter 5. Meanwhile, instead of the optical filter device 6 and thefilter control unit 15, the optical filter device 6A and the filtercontrol unit 15A may be used.

Thereafter, when the spectrally separated light is received by the lightreceiving element 137, a light receiving signal according to thequantity of received light is output to the signal processing unit 144through the light receiving circuit 147. In this case, it is possible toprecisely extract the Raman-scattering light, which is a target, fromthe wavelength variable interference filter 5.

The signal processing unit 144 compares the spectrum data of theRaman-scattering light corresponding to the gas molecule, which is thedetection target acquired as described above, with data which is storedin a ROM, and determines whether or not there is an objective gasmolecule, thereby specifying a substance. In addition, the signalprocessing unit 144 causes the display unit 141 to display the resultinginformation or outputs the resulting information from the connectionunit 142 to the outside.

Meanwhile, in FIGS. 9 and 10, the gas detection apparatus 100 in whichthe Raman-scattering light is spectrally separated using the wavelengthvariable interference filter 5 and which performs gas detection usingthe Raman-scattering light which is spectrally separated, is describedas an example. However, the gas detection apparatus 100 may be used as agas detection apparatus which specifies the type of gas by detecting theunique absorbance of gas. In this case, a gas sensor, which causes gasto flow inside the sensor and detects light absorbed into the gas inincident light, is used as the optical module of the invention. Further,a gas detection apparatus which analyzes and determines gas which flowsinside the sensor using such a gas sensor is used as the electronicapparatus of the invention. With this configuration, it is possible todetect the components of gas using the wavelength variable interferencefilter.

In addition, the invention is not limited to the above-described gasdetection apparatus as a system which detects the presence of aspecified substance. It is possible to describe a substance componentanalysis apparatus, such as a noninvasive measurement apparatus forsaccharides using the near-infrared spectrum or a noninvasivemeasurement apparatus for information of food, a living body, and amineral, as an example.

Hereinafter, a food analysis apparatus will be described as an exampleof the substance component analysis apparatus.

FIG. 11 is a diagram illustrating the schematic configuration of thefood analysis apparatus which is an example of the electronic apparatususing the wavelength variable interference filter 5.

As illustrated in FIG. 11, the food analysis apparatus 200 includes adetection device 210 (optical module), a control unit 220, and a displayunit 230. The detection device 210 includes a light source 211 whichemits light, an imaging lens 212 into which light is led from ameasurement target substance, an optical filter device 6 in which thewavelength variable interference filter 5 for spectrally separatinglight led from the imaging lens 212 is stored, and an imaging unit 213which detects spectrally separated light.

In addition, the control unit 220 includes a light source control unit221 which controls the turning on/off of the light source 211 andcontrols brightness in a case of lighting being on, the filter controlunit 15 which controls the wavelength variable interference filter 5, adetection control unit 223 which controls the imaging unit 213 andacquires a spectral image which is imaged by the imaging unit 213, asignal processing unit 224 (analyzer), and a storage unit 225.

In the food analysis apparatus 200, when a system is driven, the lightsource 211 is controlled by the light source control unit 221, and lightis irradiated to a measurement target substance from the light source211. Further, light, which is reflected in the measurement targetsubstance, is incident into the wavelength variable interference filter5 through the imaging lens 212. Therefore, it is possible to preciselyextract light having an objective wavelength from the wavelengthvariable interference filter 5. Further, extracted light is imaged bythe imaging unit 213 which includes, for example, a CCD camera or thelike. In addition, imaged light is stored in the storage unit 225 as thespectral image. In addition, the signal processing unit 224 changes avoltage value, which is applied to the wavelength variable interferencefilter 5, by controlling the filter control unit 15, and acquires thespectral image for each wavelength.

Further, the signal processing unit 224 performs arithmetic processingon data of each pixel in each image, which is stored in the storage unit225, and acquires a spectrum in each pixel. In addition, the storageunit 225 stores, for example, information relevant to the components offood with regard to spectrum, and the signal processing unit 224analyzes the data of the acquired spectrum based on the informationrelevant to the food, which is stored in the storage unit 225, andacquires the ingredients of the food included in the detection targetand the content thereof. In addition, it is possible to calculate foodcalories, freshness, and the like from the acquired ingredients of foodand the content thereof. Further, when spectral distribution in an imageis analyzed, it is possible to extract some parts of test target food inwhich freshness is deteriorated, and, further, it is possible to detecta foreign substance or the like included in the food.

Further, the signal processing unit 224 performs a process of causingthe display unit 230 to display information related to the ingredientsof food, the content thereof, the calories, the freshness, and the likeof the test target which are acquired as described above.

In addition, an example of the food analysis apparatus 200 isillustrated in FIG. 11. However, with approximately the sameconfiguration, it is possible to use the invention as a noninvasivemeasurement apparatus for other information as described above. Forexample, it is possible to use the invention as a biological analysisapparatus which measures and analyzes body fluid components such asblood. With regard to the biological analysis apparatus, it is possibleto use an apparatus, which detects ethyl alcohol as the apparatus whichmeasures, for example, the body fluid components such as blood, as anintoxicated driving prevention device which detects the blood alcohollevel of a driver. In addition, it is possible to use the invention asan electronic endoscope system which includes the biological analysisapparatus.

Further, it is possible to use the invention as a mineral analysisapparatus which analyzes the components of a mineral.

Further, it is possible to apply the wavelength variable interferencefilter, the optical module, and the electronic apparatus of theinvention to apparatuses below.

For example, when the intensity of light having each wavelength ischanged over a period of time, it is possible to transmit data usinglight having each wavelength. In this case, when light having aspecified wavelength is spectrally separated using the wavelengthvariable interference filter provided in the optical module and isreceived using a light receiving unit, it is possible to extract thedata which is transmitted using light having the specified wavelength.When the data of light having each wavelength is processed using theelectronic apparatus which includes the optical module for extractingdata, it is possible to perform optical communication.

In addition, it is possible to apply the electronic apparatus to aspectroscopic camera, a spectrometer, or the like which images aspectral image by spectrally separating light using the wavelengthvariable interference filter of the invention. An infrared camera intowhich the wavelength variable interference filter is built may beprovided as an example of the spectroscopic camera.

FIG. 12 is a schematic diagram illustrating the schematic configurationof the spectroscopic camera. As illustrated in FIG. 12, thespectroscopic camera 300 includes a camera main body 310, an imaginglens unit 320, and an imaging unit 330.

The camera main body 310 is a part which is gripped and operated by auser.

The imaging lens unit 320 is provided on the camera main body 310, andguides incident image light to the imaging unit 330. In addition, asillustrated in FIG. 12, the imaging lens unit 320 includes an objectivelens 321, an imaging lens 322, and an optical filter device 6 in which awavelength variable interference filter 5 provided between the lenses isstored.

The imaging unit 330 includes a light receiving element, and imagesimage light which is guided through the imaging lens unit 320.

In the spectroscopic camera 300, light having a wavelength which is animaging target is passed through the wavelength variable interferencefilter 5, and thus it is possible to image a spectral image using lighthaving a desired wavelength. Here, when a filter control unit (not shownin the drawing) drives the wavelength variable interference filter 5with regard to each wavelength using the driving method of the inventionas described in the first embodiment, it is possible to preciselyextract image light having the objective wavelength of the spectralimage.

Further, the wavelength variable interference filter of the inventionmay be used as a band-pass filter, and it is possible to use thewavelength variable interference filter of the invention as an opticallaser apparatus which spectrally separates and transmits only narrowband light centering on a prescribed wavelength in light having aprescribed wavelength region which is emitted by, for example, a lightemitting element.

In addition, the wavelength variable interference filter of theinvention may be used as a biometric apparatus, and it is possible toapply the wavelength variable interference filter of the invention to anapparatus for certifying a blood vessel, a fingerprint, a retina, aniris, or the like using, for example, light in a near infrared area or avisible area.

Further, it is possible to use the optical module and the electronicapparatus as a concentration detection apparatus. In this case, infraredenergy (infrared light), which is emitted from a substance, isspectrally separated and analyzed using the wavelength variableinterference filter, and the concentration of a subject in a sample ismeasured.

As described above, it is possible to apply the wavelength variableinterference filter, the optical module, and the electronic apparatus ofthe invention to any apparatus which spectrally separates prescribedlight from the incident light. Further, as described above, in thewavelength variable interference filter of the invention, it is possibleto spectrally separate a plurality of wavelengths using a single device,and thus it is possible to precisely measure the spectra of theplurality of wavelengths and detect a plurality of components.Therefore, compared to an apparatus according to the related art, whichextracts a desired wavelength using a plurality of devices, it ispossible to promote the miniaturization of an optical module or anelectronic apparatus, and it is possible to suitably use the wavelengthvariable interference filter of the invention as, for example, a mobileor vehicle optical device.

In addition, a detailed structure in the implementation of the inventioncan be appropriately changed to another structure in a region in whichit is possible to accomplish the object of the invention.

The entire disclosure of Japanese Patent Application No. 2014-108907filed on May 27, 2014 is expressly incorporated by reference herein.

What is claimed is:
 1. An MEMS driving device comprising: an MEMSelement that includes a pair of substrates and an electrostatic actuatorwhich changes a gap dimension between the pair of substrates; avibration detection unit that detects vibration which is added to theMEMS element; and an actuator control unit that applies a feed-forwardvoltage based on a detected value of the vibration detection unit to theelectrostatic actuator.
 2. The MEMS driving device according to claim 1,wherein the electrostatic actuator includes a bias actuator and acontrol actuator which is provided independently from the bias actuator,and wherein the actuator control unit applies the feed-forward voltageto the bias actuator and applies a feed-back voltage according to thegap dimension between the pair of substrates to the control actuator. 3.The MEMS driving device according to claim 1, further comprising: a basesubstrate to which a part of the MEMS element is fixed, wherein thevibration detection unit detects vibration of the MEMS element withregard to the base substrate.
 4. The MEMS driving device according toclaim 3, wherein an end of at least one of the pair of substrates isfixed to the base substrate, and wherein the vibration detection unitdetects vibration at a free end on a side which is opposite to the endof the substrate.
 5. The MEMS driving device according to claim 3,wherein at least one of the pair of substrates includes a firstelectrode which faces the base substrate, wherein the base substrateincludes a second electrode which faces the first electrode, and whereinthe vibration detection unit detects the vibration based on anelectrostatic capacity between the first electrode and the secondelectrode.
 6. The MEMS driving device according to claim 1, wherein theMEMS element is a wavelength variable interference filter that includesreflection films which are provided on surfaces of the pair ofsubstrates facing each other, and that selects and emits light having aprescribed wavelength from incident light which is incident to the pairof reflection films facing each other.
 7. An electronic apparatuscomprising: an MEMS driving device including an MEMS element thatincludes a pair of substrates and an electrostatic actuator whichchanges a gap dimension between the pair of substrates, a vibrationdetection unit that detects vibration which is added to the MEMSelement, and an actuator control unit that applies a feed-forwardvoltage based on a detected value of the vibration detection unit to theelectrostatic actuator; and a control unit that controls the MEMSdriving device.
 8. An MEMS driving method which drives an MEMS elementthat includes a pair of substrates and an electrostatic actuator whichchanges a gap dimension between the pair of substrates, the MEMS drivingmethod comprising: detecting vibration which is added to the MEMSelement; and applying a feed-forward voltage based on the detectedvibration to the electrostatic actuator.